Compensated valve



March 12, 1940.

V. F. DAVIS COMPENSATED VALVE Filed Hay 22, 1957 4 Sheets-Sheet 1 ATTORNEY March 12, 1940. v, F. DAvls 2,192,963

couPENsATED VALVE Filed ay 22, 1937 4 Sheets-Sheet 2 `--mm 133mm H3;

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ATTORNEY March 12, 194. V, F. DAVIS 2,192,963

COMPENSATED VALVE Filed Ilay 22. 1957 4 Sheets-Sheet 3 March 12, 1940. Vv F, DAvls 2,192,963

cournnsun vALvE Filed nay 22. 193'? 4 sheets-sheet 4 Patented Mar. l2, 1940 PATENT `OFFICE commisurati vALvE Verrier poration o! New Jene! F. Davia. Welt Orange, N. J., assigner-to Atlas Valve Company, Newark N. J., a ecrappueaunn my zz, i931, serai un. 144,145 3 claims. (cl. 1st-cs) Bly-present inventionrelates to valves and particularly to a type which may be termed a compensating valve.

Various types oi valves have long been known l to the art,.which may be opened to control the ilow of fluid. In so tar as I am aware. however, it has been exceedingly dilcult to so operate the valves that the ilow of fluid or pressure may be controlled to a fine degree or within preselected limits without what is termed a ,"hunting action Aof the valve. While a valve constructed in accordance with my present invention is readily adaptable to many purposes, it is of particular I utility when employed in connection with maintaining a substantially constant uid level or volume.

For example, many municipalities have sew- 'erage treating plants for storm drainage and inasmuch as the treating capacity of such plants is more or less limited to a maximum volume, some provision must necessarily be made to restrict the ilow of fluid so as to confine it to such capacity as the treating plant can accommodate.

It is the usual practice with most municipal treating plants to provide a reservoir oi a preselected capacity from which the ud flows to the treating plant. Since the rate of ow from this reservoir to the treating plant lters is more or less at a constant rate it is necessary that drainage ow to the reservoir be controlled so that a substantially constant level be maintained. To this end it is customary to provide a sluice gate which is opened and closed for controlling the iluid level in the reservoir` so that it may be filled at the same rate as the iluid is drawn off to thus limit the flow to the treating plant.

It is accordingly an object of my present invention to provide a valve which is automatically operable to control the rate of iiuid ilow.

' Another object of my present invention is the provision of a valve automatically operable to maintain a substantially constant iiuid level.

Another object of my present invention is the provision of a compensating valve automatically operable to limit iluid iiow and which is exceedingly sensitive to changes in iluid level so as to conilne the latter to such comparatively small limits as to substantially constitute a constant level. 1

A further object of my present invention is the provision of a compensating valve operable to control a sluice gate so as to limit uid flow to a reservoir.

Still further objects of my present invention will become obvious to those skilled in the art by reference to the accompanying wherein:

Fig. l is a schematic side view partly in crosssection showing my novel valve in conjunction with a sluice gate for controlling fluid flow;

Fig. 2 is a schematic frontview oi a sluice gate utilizing a valve constructed in accordance with drawings my present invention;

Fig. 3 is a top plan view of a' portion of my valve operating mechanism with portions thereof broken away to better illustrate the device;

Fig. 4 is a side view in cross-section of the portion of the valve operating mechanism taken on line IV--IV of Fig. 3;

Fig. 5 is a cross-sectional view taken on the line V-V of Fig. 3 and looking in the direction indicated by the arrows;

Fig. 6 is a fragmentary cross-sectional view taken on the line VI-VI of Fig. 4 looking in the direction indicated by the arrows;

Fig. 7 is a front elevational view partly in cross-section of a compensating valve constructed in accordance with my present invention;

Fig. 8 is a side elevational view in cross-section of my compensating valve taken on the line VIII-VIII oi Fig. "l:

Fig. 9 is a top plan view of my compensating valve as shown in Figs. 7 and 8;

Fig. 10 is a schematic view partly in cross-section showing operation of my compensating valve for controlling a sluice gate to limit uid iiow;

Fig. 11 is a further schematic view partly ing cross-section showing the open position of my compensating valve to cause closure of a sluice gate, and

Fig. 12 is a still further schematic view partly in cross-section showing my compensating valve in a closed position.

Referring now to the drawings in detail I have shown in Fig. la reservoir 5 of the type normally employed with the usual municipal sewerage treatment plants which may be formed of reinforced concrete and provided with a wall 6 and barrier 1. The wall B is provided with a sluice gate 8 of suitable metal or the like which does not readily deteriorate. This gate 8 is arranged to slide in slots 9 formed in a metal frame l0, the latter of which is embedded in the concrete wall 6 so as to form a seal therewith. The sluice gate frame' is oi substantially rectangular conguration and at its upper horizontal portion is of enlarged cross-sectional area, 'as shown at l2, to form a support for an annular ilange or the like I3. Supported by this ange i3 above the reser- 55 voir level is a cylinder I4 provided with rs piston I5 (Fig. 10) the arm I 6 of which extends through a suitable stuffing box or the like to'make it fluid tight.

The piston arm I8 passes downwardly through the annular flange I3 and is rigidly 'secured at one side thereof to the sluice gate 3 while its other side is formed into a rack bar by being provided with teeth i1.v

Secured to the gate frame I8 in any suitable manner, such as by bolts I8, is a plate I9 with its major surface spaced from the frame by having its ends disposed at right angles to the frame I0 or by having spacing lugs which thus forms a U-shaped configuration.

A shaft 20 is journaled in the inwardly turned ends of the plate I9 and, at a point coinciding with the teeth I1 ofthe piston arm I6. is provided with a pinion gear 22 which meshes with the rack bar I1. In order to cause rotation of the shaft 28, with attendant manual raising or lowering of the sluice gate 8 which is rigidly secured to-the rack bar I1, it is provided at one end thereof withV a bevel gear 23. Engaging this bevel gear is another bevel gear 24 carried by a vertically extending shaft 25 which shaft is journaled in suitable bearings 26 and is provided with a hand wheel 21 disposed above the reservoir level so as to be readily accessible to an operator;

Accordingly, when it is desired to manually raise or lower the sluice gate 8 itis only necessary for the operator to depress the hand wheel 21 thus causing downward movement of the shaft 25 with engagement of the normally disengaged bevel gears 23 and 24. Upon rotation of the hand wheel 21 there will follow rotation of the shafts 25 and 28. Since the pinion gear 22 is rigidly secured to the shaft 2li and this latter gear meshes with the rack bar I1 to which the gate 8 is secured, the gate is caused to move either upwardly or downwardly in the slots 9 depending upon the direction of rotation of the hand wheel 21.

The foregoing description of the construction and manual operation of the sluice gate 8 is Well known to the prior art, but since mypresent invention pertains to a novel valve for automatically operating such a sluice gate, it will be described in connection therewith although, :as previously pointed out, it is susceptible to a variety of usages.

For the purpose of automatically operating my compensating Valve, as hereinafter more fully described, the plate I9 has a housing 28 secured thereto in a suitable manner such as by bolts 29. By reference more particularly to Figs. 3 to 6, inclusive, it will be noted that a short shaft 30 is suitable journaled therein and rigidly secured to this shaft is-a reduction gear 32 which meshes with the pinion gear 22. In addition the housing 28 is provided with an elongated shaft 33 journaled therein which extends from the reduction gear compartment to a further compartment of slightly less diameter.

An additional reduction gear 34 is secured to the shaft 33 in line with the reduction gear 32 so that upon movement of the rack bar i1 there will be rotation not only of the gear 22 but also rotation of the reduction gears 32 and 34. The protruding portion of the elongated shaft 33 is suitably threaded and mounted thereon is a nut 35. In order to prevent rotation of this nut with the shaft 33 it is provided with a lug 36 disposed between a pair of similar lugs 31 forming arcanes a rigid part of the housing 23. By this construction the vnut 35 is caused to move longitudinally of the shaft 33 in one direction 'or the other depending-upon the direction of rotation of the snaft 33.

Mounted within the housing 23 is a bellows 33 preferably of metal, with oneof its ends, which may be termed a diaphragm, rigidly secured to the nut 35. 'Ihe opposite end of this bellows 33 also .constituting a diaphragm. is provided with a threaded extension protruding exteriorly of the housing 28 and is held rigidly in piace by a fitting 38. This tting constitutes substantially an elbow having a passageway extending therethrough which communicates with the interior of the bellows 33 and. in line with the longitudinal axis oi the bellows 33, the fitting 33 is provided with a bleeder valve in the form of a set screw or the like 43. A conduit 42 is connected to the ntting 33 which extends to my compensating valve so that the latter is operated in response to contraction and expansion of the bellows 38 as hereinafter more fully described.

The valve proper comprises a pair of cylinders 43 and 44 (see Figs. 'I to 9) mounted exteriorly of the reservoir upon a pair of bracketawhich inder 43 is provided with a sleeve 46 snuglyV fitting the interior thereof but of slightly less length, thus forming chambers 41 and 43 at the y top and bottom of the cylinder. A small longitudinal bore 49 is provided in the sleeve 43 which communicates with a pair of transverse bores 33 and 52 as well as the chambers 41 and 43 and. intermediate the transverse bores, the sleeve 43 is provided wth an opening 53 which aligns with an opening in the cylinder wall engageable by a conduit 54 extending from a suitable source of iiuid supply, such as a compressed air source, the usual municipalwater supply, or any other .hydraulic pressure source.

A pairV of annular passages 55 and 56 are provided in the wall of the cylinder 43 in alignment with the transverse bores 58 and 52 of the sleeve 46 and the annular passageway 55 communicates with a threaded opening engaged by a'conduit 51 extending to the bottom of the sluice gate operating piston I5, while the annular passageway 56 likewise communicates with a threaded opening engaged by a. similar conduit 58 extending to the top of this same piston.

A passageway 59 (Fig. '7) interconnects the two chambers 41 and 48 and for the purpose of exhausting iiuid after operation of the valve, the chamber 48 is provided with a port 63 in alignment withfa threaded opening in the cylinder wall engaged by a conduit 62 which may extend to a suitable opening 63 (Fig. l) so that the uid is discharged into the reservoir 5.

In order to cause the flow of fluid through the valve, with attendant movement of the sluice gate 8, a piston 64 is disposed within the cylinder 43 and sleeve 46 which extends through suitable packing fianges'65 and 66 and at the upper extremity thereof is threadedly engaged by a bifurcated member 61 held in' place by a lock nut 68. The diameter of the valve piston 34 is less than that of the longitudinal bore 49 but at spaced points along its length, equal to the spacing of the transverse bores 53 and 52, the piston -64 is provided with enlarged portions 69 and 13 in the form of spools which snugly t the longitudinal bore 49 of the sleeve 46. Accordingly when the valve piston 64 is in the neutral position, as shown in Fig. 8, fluid pressure admitted by the conduit 54 and opening 53 is retained in the annular chamber formed between the valve piston 84 and the sleeve 48 by the enlarged portions or spools 88 and 18.

Upon downward movement of the valve piston 64 together with the spools 68 and 18 iiuid pressure will be forced through the longitudinal bore 50 and through the transverse bore 52, annular passageway 56 and conduit 58 tofthe top of the piston i5. This pressure accordingly forces downward movement of the piston I and sluice gate 8 to thus vrestrict the further flow of water into the reservoir. During downward movementl of the piston I5-the uid in the cylinder beneath the piston is forced through conduit 51 and since the upper valve piston spool 18 has opened communication between the: transverse bore 58 and upper chamber 41, the iiuid iiows through the latter, thence by means of passageway 58 to the lower chamber 48 anil through exhaust conduit 82 and opening 83, where it is discharged into the reservoir 5. y l l When the valve piston 64 with its integral spools 88 and 18 is moved upwardly the cycle of operation is merely reversed by communication of the source of hydraulic pressure being established directly with the transverse bore 58, annular passageway 55 and conduit 51, to the bottom of piston l5. The iluid above the latter piston is thus forced through conduit 58, annular passageway 58, transverse bore 52, and longitudinal bore 48 directly into chamber 48 vfrom which it again discharges through exhaust conduit 62 and opening 63 into the reservoir 5.A 'Ihe application of fluid pressure to the underside of the piston l5 thus opens the sluice-gate 8 to allow the iiow of additional sewerage into the reservoir 5.

In order Vto automatically cause operation `of the valve piston 84, together with the piston l5 and movement of the gate 8, to maintain the volume or capacity of iluid in the reservoir 5 within very narrow preselected limits, I provide a compensating mechanism in conjunction with my valve which operates in response to exceedingly small changes in fluid level without any attendant hunting action of the valve. 'I'his latter mechanism, in addition to that previously described as contained within the housing 28, comprisesa housing 12 mounted upon the pedestal 45 adjacent the cylinder 43 and which may form an integral part of the same casting.

As shown more particularly in Fig. l the housing 12 is provided with a partition 13 dividing it into two compartments 14 and 15. The conduit 42, which as before explained threadedly engages the fitting 38 and communicates with the bellows 38 disposed within the housing 28,- extends to the compartment 14 and'threadedly engages the housing 12, as can be seen more clearly from Fig. 9.

Positioned within the compartment 15 is a bellows 1 similar to the bellows 38 which .is provided wi a hollow extension protruding through the partition 13 and a lock nut 11 holds the 'bellows 16 securely in place so that the interior of the latter is in communication with the compartment 14\and also with the bellows 38 by virtue of the conduit 42. 'Ihe opposite end or diaphragm of the bellows 16 has a portion 18 rigidly secured thereto which extends loosely through the housing cover 18. The extremity of' this portion 18 `is threaded and supports aV bifurcated member 8l similar to that oi' the member 61 carried by the valve piston 64. A small passageway 82 extends longitudinally of the portion 18 and is closed at its upper endV by a set .screw or the like 83 having a bleeder or pressure valve 84 secured thereto.

In order` to fill what I termV my compensating mechanism, comprising the bellows 38 and 16, with iluid the cylinders 43 and 15, which as before stated may be cast enbloc, are provided with a passageway 85 `(Figf'). This passageway communicates with the source of hydraulic.

pressure by opening into the annular passage 56 (Fig. 8). It should be noted that the valve piston 64 must be-in a` predetermined position, or in other words, with the spool 68 downward allowing fluid to flow from the longitudinal bore through the transverse bore before iluid will flow through the passageway 85.' 'I'he cylinder 15 is also provided with a suitable needlevalve or the like 88 (Figs. 1 `and 9) which is opened to allow the compensating mechanism to be filled.

Opening of this needle valve after the valve piston 64 has been properly set, thus allows fluid to flow into the chamber 'I4 from which it flows to both bellows 38 and 16. During the initial lling trapped air may be rapidly released by loosening the set screw 83 or more slowly as the pressure builds up by the bleeder valve 84. Once the compensating mechanism has once been filled it need not be further disturbed unless a leak develops or it is drained by opening the bleeder valve 40 on the fitting 38 adjacent the gate 8.7

Operation of the valve piston 64, together with the portion of the compensating mechanism encased in the adjacent housing 15 is eilected by the rise and fall of a metallic float 81 (Fig. 1l whichis disposed within the reservoir 5. This float is connected by means of a rod or the like 88 to a bar 88, the latter of which is pivoted at 88 to a ilange 82 formed on the pedestal 45. A similar bar 83 ispivotally connected at 94 and 85 to the bifurcated members 61 and 88 and the bar 83 is interconnected with the bar 89 by a pivoted link 86 having xed collars or stops 81 and 88. By this link and bar arrangement the float 81 is thus operably connected to the valve piston 64 and the bellows 16.

'I'he operation of my'compensating valve may be explained as follows: At normal operating conditions where the water in the reservoir 5 is consumed or utilized at the treating plant as will remain at its normal position such as shown in Figs. 1, 2 and 10.\ This will accordingly main- Y tain the valve piston 64 in a neutral position, such as shown in Fig. 10, due to the action of the float and the compensating mechanism. Should the water level A" (Fig. 10) rise from storm drainage or the like, this would normally cause a similar rise in the reservoir level B and upward movement of the float 81 with an increase of volume above that which the treating plant could accommodate.

To prevent the occurrence of such condition and to maintain a substantially constant volume of water within the reservoir 5, the upward movement of the iioat actuates the compensating valve to cause movement of the gate in the following manner. Upward movement of the float 81 causes movement of the horizontal bar 88 about its fixed pivot 88 which in turn causes upward movement of the horizontal bar 83 by virtue of the pivoted link' 86.

At this time the gate 8 will not have left its normal position with the result that the bellows 16v will be expanded and the point 55- iunctions as the pivot for the rod 53, thus causing downward movement of the valve piston 6I. When the .valve piston 64 moves downwardly the respective spools 68 and 10 likewise move downwardly allowing the pressure fluid to ow through the transverse bore 52, annular passage 56 and conduit 56 to the top of piston I5. This pressure accordingly forces the piston I5 downwardly and since the gate 8 is rigidly secured thereto it is also moved toward closed position. At this time the iluid on tudinal movement of the nut 35 along the threaded portion of the shaft 33 in the guide formed by the depending lugs 31. Mlovement of the nut to the left as shown in Figs. 3 and 4 thus compresses the bellows 38 since one diaphragm thereof is maintained stationary. The fluid thus contained in the bellows 38 is forced through the conduit l2 causing an expansion of the bellows 16. Expansion of the latter accordingly applies an upward force to the bifurcated member Il which carries with it the horizontal bar 33.

Since thepoint at this time no longer functions as a. xed pivot, the pivot point forI the bar 93 now shifts to the point where the link 86 is connected thereto, as shown in Fig. 12, inasmuch as such point remains xed, due to the action of the float 81 and lower horizontal bar 68. 'I'he valve piston 64 will then move upwards gradually shutting oft' the flow of pressure fluid to the top of piston I5 until the valve piston again reaches its neutral position as shown in Figs. 8, 10 and 12. If there is no further change in the water level within the reservoir 5 the entire mechanism, including the gate 8, comes to rest until a new change in level occurs.

Moreover, since my compensating mechanism causes a gradual closing and opening of the valve '64 even prior to an actual reciprocal change in fluid level, there results not only a fine degree of control of the uid level within the reservoir, but also a complete elimination of undesired reciprocation of the valve 64 and piston I5 which is commonly known to the art as hunting inasmuch as both the valve and piston gradually come to rest without oscillation.

Should the water level within the reservoir 5 fall, the gate is then opened to allow more water to flow therein. When the oat 81 moves downwardly a small force is again applied through the bar 89 to the small horizontal bar 93. Since the bellows 16 is at this time expanded the point 85 functions as a fixed pivot for the movement causing a raising of the valve piston 64. Pressure fluid is accordingly forced through the conduit 51 to the underside of the gate piston I5 with the uid above the piston being forced through the valve to discharge passage 63 in the manner previously explained. Such force on the piston I5 accordingly raises the gate 8 with opposite rotation of the respective reduction gearing 22, 23, and 3lY accompanied by expansion of the bellows 38. This relieves the pressure on the bellows 16 with attendant lowering of the pivot S5 and the vulve Apiston 64, since the pivotal connection between the link 96 and bar 93 now functions as the pivot. 'I'he valve piston 64 is thus gradually lowover, by changing the ratio of the reduction gear-v ing forming a part of my mechanism the upper and lower limits of water level within a reservoli or receptacle can be varied within comparatively wide limits ranging from an inch or so to a foot or more without in any way impairing the responsiveness of the mechanism to iluid level changes.

Although I have shown and described one speciilc embodiment of my present invention, I do not desire to'be limited thereto as various other modifications thereof may be made without departing from the spirit and scope of the appended claims.

What is claimed is:

1. 'I'he combination with a uid motor including a piston, a reservoir having an inlet for liquid ow, a member extending from said piston, a gate for said inlet connected to said member, a compensating valve, a piston ann extending from said valve, a fluid pressure supply for said valve, a float in said reservoir, a conduit leading from said valve for the passage of pressure fluid to one side of said piston, a conduit leading from the other side of said piston to said valve for the removal of pressure fluid to cause a. movement of said piston, a hydraulic expansible and contractible element, a link having one end pivoted to an end of said piston arm, a connector member extending from said oat and pivotally attached to the other end of said link, a fulcrum member extending from said element serving as a fulcrum to cause said link upon anupward movement of said oat to actuate said piston arm causing a flow of liquid above said piston to lower said gate, a hydraulic bellows, a liquid conduit connecting said bellows and said element, said bellows having one end fixed and the other end free to move, a member movable when rotated to move said free end of said bellows, a gear on said last mentioned member, a rack on said gate and reduction gearing operable upon a movement of said rack to move said movable member to compress said bellows causing said liquid to expand said element and lift said link to operate said valve.

2. The combination with a fluid motor including a piston, a reservoir having an inlet for liquid iiow, a member extending from said piston, a gate for said inlet connected to said member, a

. compensating valve, a piston arm extending from said valve, a iluid pressure supply for said valve, a float in said reservoir, a conduit leading from said valve for the passage of pressure fluid to one side of said piston, a conduit leading from the other side of said piston to said valve for the removal of pressure iluid to cause a movement of said piston, a hydraulic expansible and contractible element, a link having one end pivoted to an end of said piston arm, a connector member extending from said oat and pivotally attached to the other end of said link,'a fulcrum member extending from saidv element serving as a fulcrum to cause said link upon an upward movement of said oat to actuate said piston arm causing a ow of liquid above said piston to lower said gate, a hydraulic bellows, a. liquid conduit connecting said bellows and said element and means operably connecting said gate to said bellows comprising reduction gearing connected to said bellows and rotatable by movement of said gate to cause contraction of said bellows and expansion of said element with attendant raising of said link and reverse movement of said piston arm, in response to relatively small movement of said gate.

3. The combination with a uid motor including a piston, a reservoir having an inlet for liquid ilow, a member extending from said piston, a gate for said inlet connected to said member, a compensating valve, a piston arm extending from said valve, a uid pressure supply for said valve, a float in said reservoir, a conduit leading from 20 said valve for the passage of pressure fluid to one side of said piston. a conduit leading from the other side of said piston to said valve for the removal of pressure fluid to cause a movement of said piston, a hydraulic expansible and contractible element, a link having one end pivoted to an end of said piston arm, a connector member extending from said iioat and pivotally attached to the other end of said link, a fulcrum member extending from said element serving as a iulcrum to cause said link upon an upward movement of said float to actuate said piston arm causing a flow of liquid above said piston to lower said gate, a hydraulic bellows, a liquid conduit connecting said bellows and said element, means for holding one end of said bellows, a threaded shaft, a nut integral with the other end of said bellows, a gear in said shaft, a rack on said gate and reduction gearing between said rack and said gear for causing relatively slight movement of said nut to compress said bellows during a rela.- tively long movement of said gate.

,VERNER F. DAVIS. 

